Fragrance control

ABSTRACT

Fragrance control is provided by articles of manufacture including various fragrancing objects, methods of using such objects, and systems that employ one or more such objects. The fragrancing object can be easy to manufacture, long lasting, provide fragrance that is consistently released over time, provide an indication to the user that the object needs to be replaced, and can hold a desired ratio of fragrance. The fragrancing object can include a first material comprising a polyether block amide, a second material comprising a polyolefin elastomer (POE), and a fragrance component such as a fragrance oil.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims the benefit of U.S. Provisional Patent Application Ser. No. 61/700,926, filed on Sep. 14, 2012. The entire disclosure of the above application is incorporated herein by reference.

FIELD

The present technology relates to articles of manufacture, systems, and processes for fragrance control of one or more various environments. In particular, fragrance control can be employed in an environment, such as a lavatory environment, in order to provide a pleasant fragrance and/or to neutralize or reduce the impact of one or more unpleasant odors.

INTRODUCTION

This section provides background information related to the present disclosure which is not necessarily prior art.

It is often desirable to control the fragrance of certain environments, either to provide a particular fragrance as part of a particular experience or brand identity, for example, or to neutralize or reduce the impact of an unpleasant odor that may be encountered in the particular environment. Both residential and commercial spaces can often benefit from some type of fragrance control. As one example, fragrance control within a lavatory can provide a user with a more pleasant experience and can complement other aspects and perceptions of the environment, such as general cleanliness.

Various fragrancing objects are commonly used to mask or eliminate undesirable odors and emit a preferable scent. Many types of fragrancing objects are available, including those having liquid fragrances or fragrance oils, or plastic objects coated in a fragrance. Fragrancing objects may operate in various ways, including plug-in or spray mechanisms, and may emit or evaporate a fragrance over time. As a non-limiting example, U.S. Patent Application Publication No. 2011/0296597 to Brown et al. discloses an air freshening article that includes a body that is formed from a fragranced plastic. The entire disclosure of the above-mentioned patent application is hereby incorporated by reference.

Some ways of providing environmental fragrance control exhibit various shortcomings. For example, some fragrancing objects are not capable of holding a desired amount or ratio of a fragrancing component, such as a fragrance oil, in comparison to other materials included in the fragrancing object, and may not be easy to manufacture or provide the desired performance. Some fragrancing objects do not provide an optimal release of fragrance over a long period of time and do not provide scent coverage throughout an environment.

It would be desirable to provide fragrance control including a solid state fragrancing object that is easy to manufacture, long lasting, provides fragrance that is consistently released over time, provides effective scent coverage of an environment, and that provides holds a desired amount or ratio of a fragrant material.

SUMMARY

The present technology includes articles of manufacture, systems, and processes for environmental fragrance control that use a solid state fragrancing object that is easy to manufacture, is long lasting, provides fragrance that is consistently released over time, and holds a desired amount of fragrance.

In some embodiments, a method of fragrance control for an environment is provided, where the method includes determining parameters of the environment, mapping at least one fragrance zone for the environment based on the parameters, and outputting a number and a location of the mapped fragrance zones. The parameters include a size of the environment and a number of fixtures in the environment. The at least one fragrance zone is defined by a position of at least one solid state fragrancing object within the environment, each solid state fragrancing object including a fragrancing component. The at least one fragrance zone is configured to include one or more of the fixtures.

In certain embodiments, a method of fragrance control for an environment includes determining parameters of the environment, where the parameters include a size of the environment and a number of fixtures in the environment. At least one fragrance zone is mapped for the environment based on the parameters of the environment with the fragrance zone defined by a position of at least one solid state fragrancing object within the environment. Each solid state fragrancing object includes a fragrancing component. The at least one fragrance zone is also configured to include one or more of the fixtures. A number and a location of the mapped fragrance zones are then provided as output. One or more solid state fragrancing objects are packaged based on the number and the location of the mapped fragrance zones and the one or more solid state fragrancing objects are shipped.

In various embodiments, a method of fragrance control for an environment comprises determining parameters of the environment, mapping a plurality of fragrance zones for the environment based on the parameters of the environment, and outputting a number and a location of the mapped fragrance zones. The parameters include a size of the environment and a number of fixtures in the environment. The plurality of fragrance zones is defined by a position of a plurality of solid state fragrancing objects within the environment. Each solid state fragrancing object includes a fragrancing component and each fragrance zone is configured to include one or more fixtures. A number and a location of the mapped fragrance zones are provided as output.

Further areas of applicability will become apparent from the description provided herein. The description and specific examples in this summary are intended for purposes of illustration only and are not intended to limit the scope of the present disclosure.

DRAWINGS

The drawings described herein are for illustrative purposes only of selected embodiments and not all possible implementations, and are not intended to limit the scope of the present disclosure.

FIG. 1 depicts a first embodiment of a solid state fragrancing object, where panel A shows a solid material and a mount, panel B shows the solid material positioned to engage the mount, and panel C shows the solid material coupled to the mount.

FIG. 2 depicts a second embodiment of a solid state fragrancing object, where panel A shows a solid material and a mount, panel B shows the solid material coupled to the mount, and panel C shows an end view of the solid material coupled to the mount.

FIG. 3 depicts a third embodiment of a solid state fragrancing object, where panel A shows a solid material and a mount, panel B shows the solid material positioned to engage the mount, and panel C shows the solid material coupled to the mount.

FIG. 4 depicts a fourth embodiment of a solid state fragrancing object, where panel A shows a solid material positioned within a dispenser in an enclosed position along with a mount for receiving the dispenser, panel B shows the dispenser received by the mount where the solid material is in an exposed position, and panel C shows the solid material configured as a honeycomb shaped screen.

FIG. 5 depicts a fifth embodiment of a solid state fragrancing object, where panel A shows an exploded view of a solid material placed within an enclosure having an aperture, panel B is a front view, panel C is a side view, and panel D is another exploded view that further includes a fan.

FIG. 6 depicts a sixth embodiment of a solid state fragrancing object.

FIG. 7 depicts an interface for a parameter inquiry relating to a method of fragrance control for an environment.

FIG. 8 depicts the interface of FIG. 7 with several of the parameters selected.

FIG. 9 depicts the output of a number and a location of the mapped fragrance zones resulting from the parameters selected in FIG. 8.

DETAILED DESCRIPTION

The following description of technology is merely exemplary in nature of the subject matter, manufacture and use of one or more inventions, and is not intended to limit the scope, application, or uses of any specific invention claimed in this application or in such other applications as may be filed claiming priority to this application, or patents issuing therefrom. Regarding the methods disclosed, the order of the steps presented is exemplary in nature, and thus, the order of the steps can be different in various embodiments. Except in the examples, or where otherwise expressly indicated, all numerical quantities in this description indicating amounts of material or conditions of reaction and/or use are to be understood as modified by the word “about” in describing the broadest scope of the technology.

The present technology relates to a holistic approach to providing a proper fragrance control strategy for an environment or facility. In particular, a method of fragrance control for an environment is provided where parameters of the environment are determined. Such parameters include a size of the environment and a number of fixtures in the environment. At least one fragrance zone is mapped for the environment based on the parameters of the environment. The at least one fragrance zone is defined by a position of at least one solid state fragrancing object within the environment, where each solid state fragrancing object includes a fragrancing component. The at least one fragrance zone is configured to include one or more of the fixtures. A number and a location of the mapped fragrance zones are provided as output of the method.

The fragrance control methods described herein provide guide the design and deployment of solid state fragrancing objects with respect to the size of the environment and a number of various fixtures within the environment. For example, a building manager or custodial management service can determine where and how to deploy the most effective fragrance control tools and improve odor management. The methods employ various solid state fragrancing objects. The solid state fragrancing objects described herein are easy to manufacture, long lasting, and provide fragrance that is consistently released over time, and hold a desired amount of fragrance. In particular, such fragrancing objects include one or more fragrance components that are released or volatilized over time to provide an environment with a desired fragrance to control the odor experienced in the environment.

In some embodiments, the solid state fragrancing object comprises a solid material where the solid material includes the fragrancing component. The solid material has a substantially constant cross-sectional area in a longitudinal dimension. For example, the longitudinal dimension of the solid material can represent a length where a transverse dimension substantially perpendicular to the longitudinal dimension can represent a height or a width of the solid material. In certain embodiments, the substantially constant cross-sectional area can relate to the shape of an extruder die or head used to form the solid material. The solid material has a surface area to volume ratio from about 0.5:1 to about 50:1. The surface area to volume ratio is the amount of surface area per unit volume of the solid material. The ratios provided herein are denoted as surface area:volume, but can also be written as (surface area)/(volume) or as a numerical value having units of inverse distance, where the distance (d) can be meters, inches, etc. I.e., about 0.5:1 to about 50:1 can be written as about 0.5 d⁻¹ to about 50 d⁻¹.

In various embodiments, the fragrancing object can be configured to have a certain surface area to volume ratio and can also be configured to have a certain surface area to environment volume ratio. As one example, the fragrancing object can provide a particular surface area to volume ratio, where the ratio is tailored to particular applications. In some cases, the fragrancing object can be configured with a greater surface area for a fixed volume to increase the transmission rate of the fragrance component out of the fragrancing object to the atmosphere; e.g., the fragrancing object can configured as a porous material or screen. In other cases, the fragrancing object can be configured with a reduced surface area for a given volume to reduce the transmission rate of the fragrance component out of the fragrancing object to the atmosphere; e.g., the fragrancing object can be configured as a solid shape, such as a puck or sphere. As another example, the fragrancing object can have a surface area to environment volume ratio to provide a certain transmission rate or amount of the fragrance component per atmosphere volume. In certain cases, a square inch of fragranced surface area to environmental cubic foot volume ratio range can be about 0.01 to about 0.1.

The solid material of the fragrancing object includes the fragrance component, such as a fragrance oil. Fragrance oils, also known as aroma, aromatic, and flavor oils, include single or blended synthetic compounds and/or natural essential oils. The fragrance oil can be diluted with a carrier oil or other solvent, such as various vegetable oils, mineral oil, or propylene glycol. Examples of various fragrance oils include orange, Mentha arvensis, peppermint, cedarwood, lemon, Eucalyptus globulus, Litsea cubeba, clove (leaf), and spearmint. The fragrance component can be loaded into the solid material in various amounts. For example, in some embodiments the solid material can include at least about 20% by weight of the fragrancing component and in other embodiments the solid material can include at least about 25% by weight of the fragrancing component.

Various loadings of the fragrancing component can provide for a persistent and perceptible fragrance over a given period of time. For example, in some embodiments the fragrancing component can be perceptible for at least about 30 days within an environment of 800 cubic feet surrounding the solid state fragrancing object, and in other embodiments the fragrancing component can be perceptible for at least about 60 days within an environment of 800 cubic feet surrounding the solid state fragrancing object. By perceptible, it is meant that at least 50% of people on a test panel can detect the odor. For example, the environment containing the solid state fragrancing object and an environment without the solid state fragrancing object (as a reference) are presented to a group of panelists. In comparing the fragrance present in each environment, the panelists are asked to report if they can detect a difference between the environments. The test and perceptions by the panelists can be repeated as necessary to afford statistical relevance.

In addition to the fragrancing component, the solid material can comprise one or more various materials that are substantially solid at room temperature and maintain a substantially solid form when admixed with a fragrancing component, such as a liquid fragrancing oil. In this way, the solid state fragrancing object remains substantially solid and able to retain its shape when deployed within an environment. Suitable materials include various polymeric materials and porous materials that can absorb the fragrancing component to thereby limit or control the rate at which the fragrancing component is emitted from the solid state fragrancing object.

In certain embodiments, the solid material can include a thermoplastic elastomer comprising a polyether block amide (PEBA). The PEBA can be obtained by polycondensation of a carboxylic acid polyamide with an alcohol termination polyether to provide a block copolymer with a sequence of polyamide and polyether segments. The block copolymer includes linear chains of relatively rigid polyamide and relatively soft polyether segments. Absorption and controlled release of volatile molecules (e.g., fragrancing components, fragrancing oils) can occur through the polyether phase of the material, The PEBA generally exhibits a good resistance to chemicals and some solvents. One source of a suitable polyether block amide includes PEBAX™ polyether block amides from Arkema Inc. (King of Prussia, Pa.), The PEBA can provide improved absorption and improved release of the fragrance component in comparison to other materials.

In some embodiments, the solid material can include a polyolefin elastomer (POE). Examples of suitable polyolefin elastomers include polyisobutylene (PIB), ethylene propylene rubber (EPR), ethylene propylene diene monomer (M-class) rubber (EPDM rubber). Other examples include various copolymers of ethylene and another alpha-olefin, such as butene or octene; e.g., copolymers of ethylene-butene or ethylene-octene. POEs can be produced in various ways, including use of a metallocene catalyst, as is known in the art. Various POEs can be produced using monomer components of propylene, ethylene, butene, octene and/or hexene. Two examples of suitable polyolefin elastomers are Polyolefin Elastomer 999 Offgrade (an ethene-1-octene copolymer) and ENGAGE™ 8411 polyolefin elastomer (an ethylene-octene elastomer), both from Dow Chemical Co. (Midland, Mich.).

In various embodiments, the solid material can include both a polyether block amide (PEBA) and a polyolefin elastomer (POE). The PEBA can be combined with the POE in amounts ranging from about 1% by weight PEBA with about 99% by weight POE to about 99% by weight PEBA with about 1% by weight POE. Certain embodiments of the solid material include where the PEBA makes up at least 10% of the solid material, the POE makes up to at least 40% of the solid material, and the fragrancing component makes up to at least 15% of the solid material. In various embodiments, the balance of the solid material can comprise the PEBA, the POE, the fragrance component, and/or an additional material or additive. The additional material or additive can comprise a polymeric material or can be a nonpolymeric material. For example, the solid material can include at least one additive, such as an odor neutralizer, a sequesterant, a counteractant, an enzyme, and a colorant.

The solid state fragrancing object can be formed in various shapes and sizes. The fragrancing object may include one or more separate pieces that are assembled together and/or the fragrancing object may be assembled with other materials or coupled to other components or materials. For example, the fragrancing object can be coupled to a holder or mount that is affixed to a wall, ceiling, floor, or some object within the environment. In some embodiments, the solid state fragrancing object can take the form of a rod, tube, blade, clip-on fragrance tube, slide-in fragrance blade, disk, cartridge, signage, kick plate, ornamental object, maintenance aid such as a moppable floor mat or dispenser mat, air vent or portion of an air vent, screen, a drain screen, urinal screen, or various air freshener shapes.

The solid state fragrancing object can also have an adhesive on a portion of the solid material, where the adhesive is operable to couple the solid state fragrancing object to a surface. For example, the fragrancing object can be in the form of a sheet, strip, panel, signage, or decal with adhesive on one side. The adhesive can be in the form of an adhesive backing that allows for peal-and-stick applications of the fragrancing device. The fragrancing object can take the form of signage or display a logo, and can be formed in different sizes. The fragrancing object can be located throughout an environment, where it can be affixed to fixtures, walls, and various objects, including waste receptacles, change tables, urinal mats, stalls, etc. Presence of the fragrancing object can provide fragrancing control and can also identify to an observer that a fragrance control system is being used in the environment.

With reference to FIG. 1, a first embodiment of a solid state fragrancing object 100 is shown. The fragrancing object 100 includes a solid material 110 that contains the fragrancing component. As can be seen, the solid material 110 has a substantially constant cross-sectional area in a longitudinal dimension 120. The surface area to volume ratio of the solid material 110 lies between about 0.5:1 to about 50:1. An interior portion 130 of the solid material 110 is hollow. The solid material 110 has a recess 140 running in the longitudinal dimension 120 that can be used to couple and receive a mount 150. The mount 150 can be coupled to a wall or other structure in an environment so that the solid material 110 can be easily replaced when the fragrancing component is diminished and no longer adequate. Panel A shows the solid material 110 separated from the mount 150. Panel B shows the solid material 110 positioned to slide the mount 150 into the recess 140. Panel C shows the solid material 110 coupled to the mount 150. The mount 150 allows mounting the solid material 110 such that air can circulate all around and through the solid material 110 so that fragrance is dispensed from the inside and the outside.

As depicted in FIG. 1, the solid material 110 has a tube-like shape having a transverse dimension 160 that is less than the longitudinal dimension 120. The solid material 110 is also formed with a plurality of protuberances 170 that run in the longitudinal dimension 120 and increase the surface area of the solid material 110. The protuberances 170 shown are formed as ribs or Quonset but shaped structures; however, the protuberances 170 can be formed in various other shapes and can project radially further from a remainder of the solid material 110 or project radially less from the remainder of the solid material than shown. The solid material 110 depicted in FIG. 1 also includes protuberances 170 projecting into the hollow interior portion 130. It should be noted that air can flow through the hollow interior portion 130 using the open ends of the solid material 110 and that the hollow interior portion 130 contributes to the overall surface area of the solid material 110.

The solid state fragrancing object, such as the fragrancing object 100 shown in FIG. 1, can also be used without the mount 150. In this case, the solid material 110 can be snapped onto or clipped onto a structure directly. For example, the recess 140 can allow the solid material 110 to be slipped over a length of pipe under a sink or snapped/clipped onto an edge or lip of a toilet door or stall, or onto urinal divider, in a lavatory environment.

With reference to FIG. 2, a second embodiment of a solid state fragrancing object 200 is shown. The fragrancing object 200 includes a solid material 210 that contains the fragrancing component. The solid material 210 has a substantially constant cross-sectional area in a longitudinal dimension 220. The surface area to volume ratio of the solid material 210 lies between about 0.5:1 to about 50:1. A base 230 forms one portion of the solid material 210 and a blade 240 forms another portion of the solid material 210, where the base 230 and the blade 240 run in the longitudinal dimension 220 and the blade 240 extends laterally outwardly from the base 230. As shown, the blade 240 comprises a greater portion of the solid material 210 than the base 230. In this way, the blade 240 provides a surface area exposed to the environment to release the fragrancing component. However, in other embodiments the blade 240 can comprise an equal or lesser portion of the solid material 210 than the base (not shown). The base 230 couples the solid material 210 to a mount 250 by sliding the base 230 into the mount 250. The mount 250 can be coupled to a wall or other structure in an environment so that the solid material 210 can be easily replaced when the fragrancing component is diminished and no longer adequate. Panel A shows the solid material 210 separated from the mount 250. Panel B shows the solid material 210 coupled to the mount 250, where the base 230 is slid into the mount 250. Panel C shows an end view of the solid material 210 coupled to the mount 250, with the base 230 within the mount 250 and the blade 240 projecting from the mount 250.

In some embodiments, the fragrancing objects 100, 200 shown in FIGS. 1 and 2 can be coupled to various fixtures or portions of pre-existing features in particular environments and configured in a conspicuous fashion or in an inconspicuous fashion. The fragrancing objects 100, 200 can be coupled to standard plumbing fixtures, counters, cabinetry, lavatory stalls and doors, air vents, etc. Where the fragrancing objects 100, 200 are used in a conspicuous manner, the fragrancing objects 100, 200 can be designed in various aesthetic shapes, colors, and textures that can be readily seen within the environment. Conspicuous fragrancing objects 100, 200 can therefore be part of the decor or a decor theme or can match or provide accents to the decor. Where the fragrancing objects 100, 200 are used in an inconspicuous manner, the fragrancing objects 100, 200 can be designed in various shapes, colors, and textures to blend into the environment. Discretely installing the fragrancing objects 100, 200 can prevent interference with the aesthetics of an environment and can minimize the incidence of vandalism or theft. Discrete shapes and colors can also be used where the fragrancing object 100, 200 matches or blends in with the environment location to which it is coupled. The fragrancing object 100, 200 can be configured for use in a stealth fashion to minimize conspicuousness by using darker or environment-matching colors, coupling the fragrancing object 100, 200 to preexisting fixtures or objects to make the fragrancing object 100, 200 appear to be part of the preexisting fixture or object, and/or by using the fragrancing object 100, 200 in place of preexisting objects. For example, inconspicuous fragrancing objects 100, 200 can be placed on the bottom of lavatory stalls, urinal dividers, as kick plates on doors, or used as signage.

In various embodiments, the present technology provides systems for fragrance control of an environment. A system can include a plurality of solid state fragrancing objects, with each fragrancing object comprising a solid material that includes a fragrancing component. Each solid material can have a substantially constant cross-sectional area in a longitudinal dimension and a surface area to volume ratio of about 0.5:1 to about 50:1. The plurality of fragrancing objects is arranged in the environment to provide fragrance substantially throughout the environment. For example, the system can employ fragrancing objects 100, 200 as shown in FIGS. 1 and 2 and/or other fragrancing objects as described herein. The individual fragrancing objects can each include a fragrancing component that is perceptible for at least about 30 days or at least about 60 days within an environment of 800 cubic feet surrounding the solid state fragrancing object. In this way, the fragrancing objects of the system can be deployed throughout the environment so that perceptible fragrance zones substantially overlap or nearly overlap. The system can therefore minimize space in the environment where the various fragrancing components are not perceptible and can provide a substantially constant fragrance experience as one moves through the environment. The fragrancing components in the various fragrancing objects can be the same or different, such that the system can be tailored to provide a continuous fragrance or different regional fragrances within the environment.

The plurality of fragrancing objects employed in the system can include many forms, including the various fragrancing objects described herein. For example, in certain embodiments at least one of the solid state fragrancing objects can be configured as a sign, configured as a kick plate on a door, coupled to a toilet divider or urinal divider, coupled to a toilet door, coupled to an air vent, or coupled to a pipe. The one or more of the fragrancing objects can also be conspicuously displayed in the environment and/or inconspicuously displayed in the environment. For example, one fragrancing object in the system can be configured as a conspicuous wall sconce in a lavatory, while another fragrancing object is inconspicuously placed alongside the bottom edge of a lavatory stall or urinal divider. Several fragrancing objects can be used together and formed in various shapes, designs, and colors to provide a scent design theme. For example, a fragrance control system can include a plurality of fragrancing objects displayed in an environment that have a natural theme (e.g., bamboo, leaves, etc.), identifiable object theme (e.g., bubbles), or abstract themes. Combinations of various themes can also be used.

In some embodiments, the solid state fragrancing object can be formed by extrusion, where a material and a fragrancing component are extruded to form a solid material, the solid material including the fragrancing component. The extrusion process results in the solid material having a substantially constant cross-sectional area in a longitudinal dimension and a surface area to volume ratio of about 0.5:1 to about 50:1. For example, an extruder with various dies or extruder heads can be employed to provide various cross-sectional shapes to the resulting solid material. The material and the fragrancing component may be in a liquid, semi-liquid, gel, or paste-like phase when present in the extruder, but become necessarily solid following extrusion to form the solid material. In particular, the material and the fragrancing component can be mixed in the extruder followed by extruding the material and the fragrancing component to form the solid material including the fragrancing component. The mixing can include melt-mixing the material and the fragrancing component in the extruder.

Extrusion can allow loading of the fragrancing component into the resulting solid material at levels that cannot be achieved using other means. For example, the extrusion process can provide a solid material that includes at least about 20% by weight of the fragrancing component. In some cases, the extrusion process can provide a solid material that includes at least about 25% by weight of the fragrancing component. Improved loading of the fragrancing component can be furthered by performing the extrusion process below X degrees Centigrade. In this way, loss of volatile fragrancing oils used as the fragrancing component can be minimized.

As a further example, the solid state fragrancing object can be formed as follows. A material comprising a polyether block amide and a polyolefin elastomer can be used with a fragrancing component. For example, the polyether block amide and a fragrance oil (as the fragrancing component) can be tumbled together in a drum without the addition of heat. The polyolefin elastomer is then added along with any additives, such as a colorant. The mixture of the material (i.e., the polyether block amide and polyolefin elastomer) and the fragrancing component can then be extruded, as described above.

Alternatively, the material and the fragrancing component can be processed by other means, such as blending, pre-molding, molding, forming, and various post-forming processes. Various molding methods can be used including injection molding, blow molding, rotational molding, and extrusion molding. Alternatively, different parts of the various materials and components can be mixed and molded in a batch process or in a continuous process using an extruder, for example. Examples of post forming processes include die cutting, shaping, trimming, bending, braiding, weaving, of the resulting solid material.

With reference now to FIG. 3, a third embodiment of a solid state fragrancing object 300 is shown. The fragrancing object 300 includes a solid material 310 that contains the fragrancing component and an aperture 320 configured to couple to a mount 330. A surface area to volume ratio of the solid material 310 lies between about 0.5:1 to about 50:1. The solid material 310 depicted is substantially disk-shaped; however, other shapes and dimensions can be used. The mount 330 includes a projection 340 that can be coupled to the aperture 320 of the solid material 310. The projection 340 can be configured to provide an airspace 350 between the solid material 310 and a remainder of the mount 330. In this way, the solid material 310 can also emit the fragrance component from the side facing the mount 330. Like other fragrancing objects described herein, the third embodiment of the fragrancing object 300 can be formed, colored, and/or positioned within an environment for conspicuous applications or for inconspicuous applications. It is understood that protrusions or other surface irregularities can by used to increase the surface area to volume ratio as previously described hereinabove.

With reference to FIG. 4, a fourth embodiment of a solid state fragrancing object 400 is shown. The fragrancing object 400 includes a solid material 410 and a dispenser 420, where the solid material 410 includes a fragrancing component. The solid material 410 is slidably disposed within the dispenser 420 and operable to move between an enclosed position (shown in panel A) and an exposed position (shown in panel B). The solid material 410 has a surface area to volume ratio from about 0.5:1 to about 50:1. The dispenser 420 can be coupled to a mount 430 that can be affixed to a surface, such as a wall. As shown, the dispenser 420 containing the solid material 410 can be configured as a cartridge that is loaded into the mount 430, where the dispenser 420 holds a plurality of solid materials slidably disposed therein. The individual solid materials 410 can be extended or enclosed as desired.

For example, a new solid material 410 can be extended when the fragrancing component of a previously exteneded solid material 410 is no longer effective at providing fragrancing control. Likewise, one of the solid materials 410 can include a fragrancing component that is different from another of the solid materials 410. This can allow the fragrancing provided by the fragrancing object 400 to be changed or customized as desired. The solid material 410 in FIG. 4 is depicted as a screen, in particular, a honeycomb screen. The screen shape can optimize airflow through the solid material 410 in order to release the fragrancing component. However, other shapes and forms of the solid material 410 can be employed. The various solid materials 410 in the plurality of solid materials 410 can be individually wrapped or sealed when enclosed by the dispenser 420. In this way, the fragrancing component of the solid material(s) 410 not in use can be preserved. As examples, the solid materials 410 can be exposed by peeling off an adhesive strip or wrapper, and/or the dispenser 420 may have a gasket or seal that protects the solid material 410 from exposure to the environment when enclosed.

With reference to FIG. 5, a fifth embodiment of a solid state fragrancing object 500 is shown. The fragrancing object 500 includes a solid material 510 and an enclosure 520. As shown, the enclosure 520 comprises two pieces, a transparent or translucent face plate 530 and an opaque back 540. The solid material 510 includes a fragrancing component and the enclosure 520 encloses the solid material 510. The enclosure 520 includes an aperture 550 configured to expose a portion of the solid material 510. The solid material 510 has a surface area to volume ratio from about 0.5:1 to about 50:1. The solid material 510 can be configured to move within the enclosure 520 to change the portion of the solid material exposed in the aperture 550. For example, as shown in FIG. 5 the solid material 510 can be coupled to a projection 560 on the back 540 of the enclosure 520 so that the solid material 510 can be rotated to change the portion of the solid material 510 within the aperture 550. The projection 560 may be coupled to a motor 570 operable to change the portion of the solid material 510 that is exposed in the aperture 550. The motor 570, for example, can rotate the solid material 510 at a rate tailored to provide a continued release of the fragrancing component from the solid material 510 by continuously or periodically changing the portion of the solid material 510 in the aperture 550. Furthermore, a fan 580 can be included that is operable to move air across the portion of the solid material 510 that is exposed in the aperture 550, thereby facilitating release of the fragrancing component from the solid material 510. The fan 580 can be continuously operated, timed to operate at desired intervals, or linked to an actuator, such as a motion sensor or light switch. Operation of the motor 570 and the fan 580 can also be coordinated.

As shown, the solid material 510 is in the form of a disk, but other shapes and configurations are possible. The disk-shaped solid material 510 can be marked with an indicator 590 to identify when replacement is necessary. For example, the indicator 590 can mark when the disk-shaped solid material 510 has rotated a certain distance about the projection 560. In some instances, the indicator 590 can include a stop that physically prevents the disk-shaped solid material 510 from further rotation. For example, the indicator 590 stop can interact with the enclosure 520. The disk-shaped solid material 510 can be in the form of a screen having a honeycomb structure to allow air to circulate through the disk, as depicted in FIG. 5.

With reference now to FIG. 6, a sixth embodiment of a solid state fragrancing object 600 is shown. The fragrancing object 600 is configured as a urinal screen 610 that is sized and shaped to cover at least a portion of a urinal drain. The urinal screen 610 is formed of a solid material having a fragrancing component using the various solid materials and fragrancing components as described herein. The urinal screen 610 includes a plurality of apertures 620, where the apertures 620 can vary in size, shape, and frequency across the urinal screen 610. A pick-up loop 630 can be formed therein or added to the urinal screen 610 to facilitate installation and removal of the screen 610. As described herein, the urinal screen 610 comprising the solid material and fragrancing component can be formed by extruding a material and a fragrancing component to form an extruded sheet of solid material. The extruded sheet of solid material can then be die cut or stamped to form the plurality of apertures 620.

The various fragrancing objects described herein can be formed in various colors and can be multicolored. In certain cases, solid colors or translucent colors can be used. Different colors used in combination with different mounting options and different holders or mounts as described herein allow mixing and matching of various colors and provide for an easy change from a less conspicuous stealth display of fragrancing objects to a more conspicuous and brighter display or vice versa. Likewise, design themes and scents of fragrancing components within an environment can be readily replenished or changed altogether. The various fragrancing objects described herein can also incorporate DeoEssence™ olfactory disruption technology by Arylessence, Inc. (Marietta, Ga.).

One or more of the aforementioned solid state fragrancing objects can be used in various methods of controlling fragrance for an environment. In particular, each fragrancing object can provide a fragrance zone around the fragrance object, where the fragrance zone is an area providing a perceptible amount of the fragrancing component. Fragrance zones of one or more fragrancing objects can therefore map out one or more areas in the environment that cover certain fixtures in the environment, ensuring that a person using the fixture is within the fragrance zone and has a perceptible encounter with the fragrancing component.

The method can begin by determining parameters of the environment where the parameters include a size of the environment and a number of fixtures in the environment. At least one fragrance zone is then mapped for the environment based on the parameters of the environment with the fragrance zone defined by a position of at least one solid state fragrancing object within the environment. As described herein, each solid state fragrancing object includes a fragrancing component. The fragrance zone is configured to include one or more of the fixtures. As a result, the method then outputs a number and a location of the mapped fragrance zones for the environment.

The method of fragrance control for an environment can further include various aspects. In one embodiment, the method can further include deploying one or more solid state fragrancing objects in the environment based on the number and the location of the mapped fragrance zones. For example, the fragrancing objects can be arranged within the environment to provide fragrance zones that substantially cover the size of the environment. The fragrancing zones can substantially overlap to prevent “dead space” where there is no perceptible flagrance component within the environment. The fragrancing zones can also cover all the fixtures in the environment so that a user of any fixture encounters a perceptible fragrance component of one or more of the fragrancing objects. A variety of fragrancing objects can be employed that can include a variety of fragrancing components. For example, certain fragrancing components can be associated with certain fixtures.

Other aspects include where the method of fragrance control includes packaging one or more solid state fragrancing objects based on the number and the location of the mapped fragrance zones. In this way, the method can provide a package or set of fragrancing objects that can be used to outfit the environment and provide the mapped fragrance zones or the method can provide a package or set of fragrancing objects for replenishing an existing fragrancing system in the environment. Similar to the packaging, the method can further include shipping one or more solid state fragrancing objects based on the number and the location of the mapped fragrance zones. The method can therefore be used to order a package or set of fragrancing objects that is customized to the particular parameters of the environment. A user employing the method can therefore tailor a fragrancing object or system of fragrancing objects for an environment based on particular parameters for that environment. The method can also include purchasing one or more solid state fragrancing objects based on the number and the location of the mapped fragrance zones. The purchasing can also be used in conjunction with the packaging and/or the shipping of the one or more solid state fragrancing objects based on the number and the location of the mapped fragrance zones.

Various fixtures can be included in the present methods. As one example, the number of fixtures can include a number of commodes so that the mapping overlaps at least one fragrance zone with the location of at least one commode in the environment. The number of commodes can include one commode to several commodes and the fragrance zones can include one fragrance zone encompassing the one commode or all commodes, or there can be multiple fragrance zones, where each fragrance zone covers one or more commodes. Other fixtures include one or more of the following: urinals, hand dryers, waste containers, baby changing stations, and feminine hygiene containers. With each of these various fixtures, the mapping can overlap at least one fragrance zone with the location of at least one of the fixtures in the environment.

Parameters of the environment can also include a traffic level of the environment. A size of the solid state fragrancing object, the number of solid state fragrancing objects, or the size and the number of solid state fragrancing objects can be changed in proportion to the traffic level of the environment. In this manner, the size of the fragrancing zone and/or the amount of fragrancing component emitted in the fragrancing zone can be tailored to the traffic, where more traffic may require the emission of more fragrancing component to provide a perceptible fragrancing zone. Lower traffic, conversely, may afford a lower emission of the fragrancing component. Likewise, the parameters can further include a cleaning frequency of the environment where one of a size of the solid state fragrancing object is changed, the number of solid state fragrancing objects is changed, and the size of the solid state fragrancing object and the number of solid state fragrancing objects are changed in proportion to the cleaning frequency of the environment.

As described herein, the various fragrancing objects can be formed in various colors and shapes and can be positioned in various ways throughout an environment. In some aspects, the fragrancing object can be conspicuous within the environment and in other aspects the fragrancing object can be inconspicuous in the environment. The general visibility and conspicuousness of the fragrancing object can be tailored based on a likelihood of vandalism, For example, where an environment has previously experienced vandalism or is believed to be a candidate for vandalism, the fragrancing object can be configured in an inconspicuous fashion. The likelihood of theft or tampering can be reduced, for example, where the fragrancing object is designed to blend into and match parts of fixtures or other features of the environment, or where the fragrancing object is placed out the general line of sight in the environment.

Certain environments can allow the use of a ladder to reach light fixtures, vents, or portions of the environment unattainable otherwise. However, some environments may prohibit the use of a ladder or ladder use is generally unfeasible or hazardous. If ladder use is permitted, certain fragrancing objects can be used in ladder-accessible locations, such as fragrancing objects configured to be affixed to ceiling light fixtures, air vents, or generally placed out of reach from environment occupants.

In some embodiments, the parameters further include a fragrance selection that defines the fragrancing component of the solid state fragrancing object. Particular fragrances or combinations of fragrances can therefore be selected. Mapping can accordingly place fragrance zones in the environment that all have a single selected fragrance or various fragrance zones can be associated with various fixtures, for example. The size fragrance zone and/or intensity of the fragrancing component emitted by the fragrancing object can be tailored to a fragrance level as part of the parameters of the environment. As such, the fragrance level can define one of a size of the solid state fragrancing object, the number of solid state fragrancing objects, and the size of the solid state fragrancing object and the number of solid state fragrancing objects. The number of fragrance zones can also be tailored, where one fragrance zone can substantially cover the size of the environment, including where the fragrance zone is configured to include the location of a fixture in the environment. Or, multiple fragrance zones can be mapped to cover multiple fixtures within the environment where the multiple fragrance zones substantially cover the size of the environment.

The present methods can therefore include a method of fragrance control for an environment that comprises determining parameters of the environment, mapping a plurality of fragrance zones for the environment based on the parameters of the environment, and outputting a number and a location of the mapped fragrance zones. As described, the parameters can include a size of the environment and a number of fixtures in the environment. The plurality of fragrance zones can be defined by a position of a plurality of solid state fragrancing objects within the environment, where each solid state fragrancing object includes a fragrancing component and each fragrance zone is configured to include one or more fixtures.

With reference now to FIGS. 7-9, an example embodiment of a method of fragrance control for an environment is illustrated. FIG. 7 shows an interface for a parameter inquiry relating to a method of fragrance control for an environment. FIG. 8 shows the interface of FIG. 7 with several of parameters selected. FIG. 9 shows the output of a number and a location of the mapped fragrance zones resulting from the parameters selected in FIG. 8.

The present technology provides several advantages and benefits. A building manager or custodial service can use the fragrance control methods to identify the number and location of mapped fragrance zones. Accordingly, one or more solid state fragrancing objects can be deployed in the environment based on the number and the location of the mapped fragrance zones to thereby provide effective odor control and improved practice in odor management. The number and location of mapped fragrance zones can also be stored and retrieved for later modification, repeat ordering, deployment, packaging, and/or shipping. The methods further allow the fragrance control of an environment to be optimized.

The solid state fragrancing objects can be easily deployed within an environment by using mounts or holders or by directly coupling the objects to various fixtures or features within the environment. There are no aerosols or liquids used, minimizing environmental impact and any spills or drips. For example, there is no possibility for leaky oil based wick systems to spill and no aerosol fall out on floors creating a sticky or slippery safety hazard. Likewise, there are no special storage or shipping requirements necessary with the present solid state fragrancing objects. The fragrancing objects can be mounted easily in hidden and out of the way locations to reduce theft and vandalism. Fragrance zones created by deploying a system for fragrance control can enhance the experience in the environment and reinforce a general perception of cleanliness. The system can also be mounted in various locations to optimize odor control efficacy and can be customized for environments ranging from small spaces to large spaces. Likewise, the fragrancing component can be tailored to fragrance type and strength preferences; e.g., men's fragrances, women's fragrances, lavatory environment, office environment, commercial or residential environment.

Example embodiments are provided so that this disclosure will be thorough, and will fully convey the scope to those who are skilled in the art. Numerous specific details are set forth such as examples of specific components, devices, and methods, to provide a thorough understanding of embodiments of the present disclosure. It will be apparent to those skilled in the art that specific details need not be employed, that example embodiments may be embodied in many different forms, and that neither should be construed to limit the scope of the disclosure. In some example embodiments, well-known processes, well-known device structures, and well-known technologies are not described in detail. Equivalent changes, modifications and variations of some embodiments, materials, compositions and methods can be made within the scope of the present technology, with substantially similar results. 

What is claimed is:
 1. A method of fragrance control for an environment comprising: determining at least one parameter of the environment, the at least one parameter including: a size of the environment; and a number of fixtures in the environment; mapping at least one fragrance zone for the environment based on the at least one parameter of the environment, the at least one fragrance zone defined by a position of at least one fragrancing object within the environment, each fragrancing object including a fragrancing component, wherein the at least one fragrance zone is configured to include one or more fixtures; outputting a number and a location of the mapped fragrance zones; and shipping one or more fragrancing objects based on the number and the location of the mapped fragrance zones.
 2. The method of claim 1, further comprising deploying one or more fragrancing objects in the environment based on the number and the location of the mapped fragrance zones.
 3. The method of claim 1, further comprising packaging one or more fragrancing objects based on the number and the location of the mapped fragrance zones.
 4. The method of claim 1, further comprising extruding one or more fragrancing objects based on the number and the location of the mapped fragrance zones.
 5. The method of claim 1, further comprising requisitioning one or more fragrancing objects based on the number and the location of the mapped fragrance zones.
 6. The method of claim 1, wherein the number of fixtures includes a number of commodes and the mapping overlaps at least one fragrance zone with the location of at least one commode in the environment.
 7. The method of claim 1, wherein the at least one parameter further includes a traffic level of the environment and one of a size of the fragrancing object is changed, the number of fragrancing objects is changed, and the size of the fragrancing object and the number of fragrancing objects are changed in proportion to the traffic level of the environment.
 8. The method of claim 1, wherein the at least one parameter further includes a cleaning frequency of the environment and one of a size of the fragrancing object is changed, the number of fragrancing objects is changed, and the size of the fragrancing object and the number of fragrancing objects are changed in proportion to the cleaning frequency of the environment.
 9. The method of claim 1, wherein the at least one parameter further includes a number of urinals in the environment and the mapping overlaps at least one fragrance zone with the location of at least one urinal in the environment.
 10. The method of claim 1, wherein the at least one parameter further includes a number of hand dryers in the environment and the mapping overlaps at least one fragrance zone with the location of at least one hand dryer in the environment.
 11. The method of claim 1, wherein the at least one parameter further includes a number of waste containers in the environment and the mapping overlaps at least one fragrance zone with the location of at least one waste container in the environment.
 12. The method of claim 1, wherein the at least one parameter further includes a number of baby changing stations in the environment and the mapping overlaps at least one fragrance zone with the location of at least one baby changing station in the environment.
 13. The method of claim 1, wherein the at least one parameter further includes a number of feminine hygiene containers in the environment and the mapping overlaps at least one fragrance zone with the location of at least one feminine hygiene container in the environment.
 14. The method of claim 1, wherein the at least one parameter further includes a likelihood of vandalism in the environment and at least one fragrancing object is configured in an inconspicuous fashion when there is a likelihood of vandalism.
 15. The method of claim 1, wherein the at least one parameter further includes whether a ladder can be used in the environment and at least one fragrancing object is deployed in the environment in a ladder-accessible location when a ladder can be used in the environment.
 16. The method of claim 1, wherein the at least one parameter further includes a fragrance selection that defines the fragrancing component of the fragrancing object.
 17. The method of Claim 1, wherein the at least one parameter further includes a fragrance level that defines one of a size of the fragrancing object, the number of fragrancing objects, and the size of the fragrancing object and the number of fragrancing objects.
 18. The method of claim 1, wherein the at least one fragrance zone substantially covers the size of the environment.
 19. A method of fragrance control for an environment comprising: determining at least one parameter of the environment, the at least one parameter including: a size of the environment; and a number of fixtures in the environment; mapping at least one fragrance zone for the environment based on the at least one parameter of the environment, the at least one fragrance zone defined by a position of at least one fragrancing object within the environment, each fragrancing object including a fragrancing component, wherein the at least one fragrance zone is configured to include one or more fixtures; outputting a number and a location of the mapped fragrance zones; and packaging one or more fragrancing objects based on the number and the location of the mapped fragrance zones.
 20. A method of fragrance control for an environment comprising: determining a plurality of parameters of the environment, the parameters including: a size of the environment; and a number of fixtures in the environment; mapping a plurality of fragrance zones for the environment based on the parameters of the environment, the plurality of fragrance zones defined by a position of a plurality of fragrancing objects within the environment, each fragrancing object including a fragrancing component, wherein each fragrance zone is configured to include one or more fixtures; outputting a number and a location of the mapped fragrance zones; and deploying one or more fragrancing objects in the environment based on the number and the location of the mapped fragrance zones. 